ABSTRACT
This study was focused on organic acids and metals in biofluids of wood. Without seasoning, fresh woods from spruce and bark, phloem, and heartwood from pine were used as materials, which were degraded with either microbes of oyster mushroom, baker's yeast, or lactic acid bacteria. Due to neutral pH of the fluids, ambient temperature, atmospheric pressure, and short reaction time, native wood microbe populations were supposed to be present. The water content of the fresh woods was 4 to 20%. The study showed that process methodology and experimental conditions affected the generation of lactic, citric, succinic, and adipic acids, which are considered as source chemicals in the biopolymer industry. In addition to the organic acids and metals, the process produced monosaccharides, polysaccharides, and phenolic acids such as benzoic, salicylic, cinnamic, vanillic, tannic, and conifer (ferulic) acids. Concentrations of total acids and acetic and succinic acids in pine fluids from bark, phloem, and heartwood were 58.4 g/kg and 3.5 to 6.9 g/kg, respectively. In spruce, the most dominant acids were l-lactic and l-malic acids. As for metals, Ag and Cr were detected at 0.01-g/kg quantities in pine bark. Alkali metals K, Mg, Sr, and Ca were detected at 10, 8, 1.3, and 4 g/kg, respectively.
Subject(s)
Biomass , Picea/chemistry , Pinus/chemistry , Wood/chemistry , Bacteria/enzymology , Fungi/enzymology , HydrolysisABSTRACT
Statins were separated and quantified with gas chromatography-mass spectrometry (GC-EI-MS/MS) using total ion monitoring (TIC) and multiple reactions monitoring (MRM). The MRM method in statins determination has a novelty value, since there are no previous studies on their simultaneous analysis in environmental or plant samples. The method development and optimization was challenging due to the physicochemical similarities of the silylated lovastatin, simvastatin, pravastatin, fluvastatin, and atorvastatin. The results showed that the use of MRM decreased their detection and quantification limits by factors of 2-10 compared to that obtained in TIC monitoring. The concentration calibration was made between 247.5ng/L and 9900ng/L. Limits of detection and quantification were between 50ng/L (lovastatin)-500ng/L (pravastatin) and 250ng/L (lovastatin)-1000ng/L (pravastatin), respectively. Based on the MRM results, the wood bark and phloem samples contained lovastatin, lovastatin-lactone, simvastatin, simvastatin-lactone, and pravastatin. Their concentrations were 250-3000µg/L, i.e. 4.2-50mg/kg in phloem and bark. However, they were not detected in fluids made with Pleurotus ostreatus fermentation of wood core.